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Query: EC:3.1.30.1 (
S1 nuclease
)
3,660
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In a simple eukaryote Physarum polycephalum about 13% of the genome is transcribed into abundant cytoplasmic RNA as shown by
S1 nuclease
digestion of DNA-RNA hybrids. Mild digestion of isolated Physarum nuclei with DNase I liberates a fraction of chromatin 3.5-fold enriched in sequences hybridizing by Physarum poly(A)+ RNA. This fraction is similarly enriched in
histone H4
and actin genes known to be actively transcribed in Physarum. High content (about 45%) of actively transcribed sequences in DNase-I-released fraction of Physarum chromatin makes it particularly well suited for studying the structural basis of transcriptional activation in eukaryotes.
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PMID:Transcriptionally active chromatin can be selectively released by DNase I from Physarum polycephalum genome. 246 74
The
histone H4
multigene family of Physarum polycephalum consists of two genes, H41 and H42. Both genes have an unusual structure in that they are interrupted by a small intron. The structure of the P. polycephalum H4 genes is discussed and compared to the structure of histone genes of other organisms.
S1 nuclease
analysis was used to map the 5' and 3' ends of the
histone H4
messengers. We show that the
histone H4
genes have a hybrid structure; they are interrupted by an intervening sequence, as in replacement variant histone genes of higher eukaryotes, but their 5' and 3' noncoding regions have the properties of replication-dependent histone genes: the 5' and 3' leader and trailer sequences are short, possess a 3'-hyphenated dyad symmetry element, and a CAGA sequence is found 3' to the hyphenated hairpin structure. This report also provides evidence that both genes are expressed in late G2 phase as well as in S phase and that their expression is temporally coordinated and quantitatively similar during the cell cycle.
...
PMID:Histone genes in Physarum polycephalum: transcription and analysis of the flanking regions of the two H4 genes. 249 87
By use of synchronized human HeLa S3 cells, a site sensitive to both DNase I and
nuclease S1
was identified 50-150 base pairs upstream of the ATG codon of a cell cycle-dependent
histone H4
gene. This site expanded to include a broad region of approximately equal to 300 base pairs sensitive to DNase I throughout S phase and then narrowed again to the original site after the completion of DNA replication. The level of
nuclease S1
sensitivity was greatest during early S phase, when the gene is replicated and its transcription rate is maximal. The chromatin structure of the human beta-globin gene, which is not expressed in HeLa cells, was also analyzed throughout the cell cycle, and in no case was a sub-band seen as a result of DNase I or
nuclease S1
digestion, nor were there any changes in nuclease sensitivity correlated with its replication. Thus the cell cycle-dependent chromatin alterations in this
histone H4
gene appear to be due to the coupled replication and expression of this gene rather than simply its replication. These results suggest that histone genes, as compared with developmentally regulated genes, exhibit an "intermediate" level of regulation whereby the gene is never in a completely inactive conformation, but changes in chromatin structure occur as a function of the cell cycle and expression.
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PMID:A human histone H4 gene exhibits cell cycle-dependent changes in chromatin structure that correlate with its expression. 299 68
We have examined the metabolism of human H4 histone mRNA in the nucleus and cytoplasm of HeLa S3 cells following inhibition of DNA synthesis to address the extent to which histone mRNA stability in these cellular compartments is coupled to DNA replication. The nuclear and cytoplasmic levels of histone mRNAs encoded by the pF0108A human H4 histone gene were determined by
S1 nuclease
analysis using a 32P-labeled probe that could distinguish pF0108A transcripts from those of other members of the H4 histone multigene family. Hydroxyurea treatment resulted within 15 min in a 75% reduction in the level of
histone H4
mRNA in the nucleus, which corresponds to the 85% decrease observed for H4 histone mRNA in the cytoplasm. The kinetics of nuclear and cytoplasmic H4 mRNA turnover following hydroxyurea treatment were also similar. Northern blot analysis using a 32P-labeled mitochondrial cytochrome b probe indicated that the association of cytoplasmic RNA with the nuclear fraction was less than 0.5%. Treatment of cells with a protein synthesis inhibitor resulted in a 1.3-fold increase in nuclear H4 histone mRNA levels and a 1.5-fold increase of H4 mRNA in the cytoplasm after 45 min. Together, these results indicate that nuclear and cytoplasmic H4 histone mRNAs respond similarly to metabolic perturbations that influence message stability and that mechanisms operative in the turnover of histone mRNAs in the nucleus and cytoplasm may be similar.
...
PMID:Coordinate turnover of nuclear and cytoplasmic histone messenger RNA following inhibition of DNA replication in HeLa S3 cells. 303 71
A physical map of 330 x 10(3) base-pairs near the replication origin of Myxococcus xanthus chromosome has been established already. Using DNA fragments from this region, Northern blot hybridization analysis was carried out in order to identify the genes expressed during vegetative growth. One of the genes, tentatively designated as vegA, was cloned and its entire DNA sequence was determined. The amino acid sequence of the gene product deduced from the DNA sequence reveals that the VegA protein is a very basic protein with a molecular weight of 18,700. The gene was expressed in Escherichia coli using an expression vector, and its gene product was identified using SDS/polyacrylamide gel electrophoresis. From the results of
S1 nuclease
mapping, the vegA promoter was found to contain the sequence TAGACA at the -35 region and the sequence AAGGGT at the -10 region. These two regions are separated by 18 nucleotides. Genetic analysis suggests that the vegA gene may be essential for the growth of M. xanthus. From a computer-aided search for homologies to know protein structures, it was found that the VegA protein has homologies to
histone H4
of Tetrahymena thermophila and histone H2B of sea urchin.
...
PMID:Identification of a vegetative promoter in Myxococcus xanthus. A protein that has homology to histones. 331 62
To assess systematically the structural and functional aspects of histone gene transcription within a chromosomal context, we stably integrated an extensive set of human
histone H4
gene constructs into mouse C127 cells. Levels of expression were determined by
S1 nuclease
protection assays for multiple mouse monoclonal cell lines containing these human H4 genes. For each cell line, we quantitated the number of integrated human H4 genes by Southern blot analysis. The results indicate that the expression of the human H4 gene is in part copy number dependent at low gene dosages. However, the level of expression varies among different cell lines containing similar numbers of copies of the same H4 gene construct. This result suggests that position-dependent chromosomal integration effects contribute to H4 gene transcription, consistent with the roles of long-range gene organization and nuclear architecture in gene regulation. At high copy number, the level of human H4 gene expression per copy decreased, and endogenous mouse H4 mRNA levels were also reduced. Furthermore, in vivo occupancy at the human H4 gene immediate 5' regulatory elements, as defined by genomic fingerprinting, showed copy number-dependent protein/DNA interactions. Hence, human and mouse H4 genes compete for titratable transcription factors in a cellular environment. Taken together, these results indicate cross-species compatibility and suggest limited representation in vivo of the factors involved in regulating
histone H4
gene transcription.
...
PMID:In vivo occupancy of histone gene proximal promoter elements reflects gene copy number-dependent titratable transactivation factors and cross-species compatibility of regulatory sequences. 775 57
Expression of many
histone H4
genes is stringently controlled during the cell cycle to maintain a functional coupling of histone biosynthesis with DNA replication. The
histone H4
multigene family provides a paradigm for understanding cell cycle control of gene transcription. All functional
histone H4
gene copies are highly conserved in the mRNA coding region. However, the putative promoter regions of these H4 genes are divergent. We analyzed three representative mouse H4 genes to assess whether variation in H4 promoter sequences has functional consequences for the relative level and temporal control of expression of distinct H4 genes. Using
S1 nuclease
protection assays with gene-specific probes and RNA from synchronized cells, we show that the mRNA level of each H4 gene is temporally coupled to DNA synthesis. However, there are differences in the relative mRNA levels of these three H4 gene copies in several cell types. Based on gel shift assays, nucleotide variations in the promoters of these H4 genes preclude or reduce binding of several histone gene transcription factors, including IRF2, HiNF-D, SP-1 and/or YY1. Therefore, differential regulation of H4 genes is directly attributable to evolutionary divergence in H4 promoter organization which dictates the potential for regulatory interactions with cognate H4 transcription factors. This regulatory flexibility in H4 promoter organization may maximize options for transcriptional control of
histone H4
gene expression in response to the onset of DNA synthesis and cell cycle progression in a broad spectrum of cell types and developmental stages.
...
PMID:Selective expression of specific histone H4 genes reflects distinctions in transcription factor interactions with divergent H4 promoter elements. 976 24
